Abstract: A needle actuator assembly for a drug delivery system includes a housing, a needle having retracted and extended positions, a needle actuator body received within the housing and configured to move from a pre-use position where the needle is in the retracted position to a use position where the needle is in the extended position and to a post-use position where the needle is in the retracted position, with the needle actuator having a button contact surface, and an actuator button received by the housing.

Abstract: A needle actuator assembly for a drug delivery system includes a needle actuator body having a guide surface, a needle shuttle having a cam surface, with the needle shuttle moveable along a vertical axis between a first position and a second position. The needle shuttle is configured to move between the first and second position through engagement between the guide surface of the needle actuator body and the cam surface of the needle shuttle. The assembly further including a needle received by the needle shuttle.

Abstract: A drug delivery system for injecting a medicament includes a housing, a container configured to receive a medicament including a stopper configured to move within the container and a closure, a needle in fluid communication with the container, a spacer configured to be engaged with the stopper, a first plunger, a first spring configured to bias the first plunger in an axial direction, second plunger disposed about the first plunger, a second spring configured to bias the second plunger in an axial direction. The first plunger is configured to move the spacer and the container relative to the housing via the first spring to establish fluid communication between the container and the patient needle, and the second plunger is configured to move the spacer and the stopper relative to the container via the second spring.

Abstract: The invention relates to a mounting mechanism for mounting an auxiliary device, such as a rangefinder, to a mobile device. The mounting mechanism includes an interface surface with formations to engage with a surface of the mobile device to maintain a desired orientation between the mobile device and the auxiliary device. The mounting mechanism also includes two or more arms which may be moved synchronously towards each other to clamp a mobile device engaged with the interface surface so as to maintain the mobile device centralised with respect to the interface surface.

Abstract: A device including a protecting material encapsulated metallic beam and a method of encapsulating the metallic beam using the protecting material layer are presented. The device includes a cantilever beam that includes at least about 90 Wt % of a metallic beam material, and 10 Wt % or less of a protecting material. The method of forming an encapsulated metallic beam includes the steps of depositing a first layer of protecting material over a substrate, depositing a second layer of protecting material over the first layer, depositing a metallic beam material over the second layer of protecting material, and encapsulating the beam material with a coating of the protecting material.

Abstract: A device including a protecting material encapsulated metallic beam and a method of encapsulating the metallic beam using the protecting material layer are presented. The device includes a cantilever beam that includes at least about 90 Wt % of a metallic beam material, and 10 Wt % or less of a protecting material. The method of forming an encapsulated metallic beam includes the steps of depositing a first layer of protecting material over a substrate, depositing a second layer of protecting material over the first layer, depositing a metallic beam material over the second layer of protecting material, and encapsulating the beam material with a coating of the protecting material.

Abstract: A method of making a membrane assembly is provided. The method comprises forming an inorganic membrane layer disposed on a substrate, and forming a plurality of macropores in the substrate at least in part using anodization. Further, a membrane assembly is provided. The membrane assembly comprises a filtering membrane that is coupled to an anodized substrate comprising a plurality of macropores.

Abstract: A device including a protecting material encapsulated metallic beam and a method of encapsulating the metallic beam using the protecting material layer are presented. The device includes a cantilever beam that includes at least about 90 Wt % of a metallic beam material, and 10 Wt % or less of a protecting material. The method of forming an encapsulated metallic beam includes the steps of depositing a first layer of protecting material over a substrate, depositing a second layer of protecting material over the first layer, depositing a metallic beam material over the second layer of protecting material, and encapsulating the beam material with a coating of the protecting material.

Abstract: An inorganic membrane device is provided. The device comprises a substrate having a network of pores, and a membrane layer at least partially coupled to the substrate and having a plurality of pores, wherein the pores have an aspect ratio in a range from about 1:2 to about 1:100.

Abstract: A microfluidic device with a vertical injection aperture is provided. The microfluidic device comprises a separation channel, an injection aperture disposed adjacent to and in fluid communication with the separation channel. The microfluidic device further comprises a semi-permeable filter disposed adjacent to the injection aperture, wherein the filter is configured to preconcentrate a sample in the injection aperture to form a preconcentrated sample plug during an injection operation, and wherein the sample plug flows downwardly from the injection aperture to the separation channel during an electrophoresis operation.

Abstract: A system and method for prescription therapy management and compliance are provided. The system framework integrates primary databases from pharmacies, pharmacy benefit managers (PBMs), health plans, and EHR providers with a secondary database system, user interface, and wireless messaging platform, in order to extract and aggregate user-specific prescription data and make it available to users through a personalized account and as a part of a wireless prescription reminder service. The system helps users access, aggregate, manage, update, automate, and schedule the prescriptions they are currently taking. Users receive real-time wireless prescription dosing reminders based on their prescribed drug, dosage, and other indications, tailored to each individual's daily schedule.

Abstract: An electrical through-connection, or via, that passes through a substrate to a bus on a first surface of the substrate. The via may be configured with an interlock such that the electrically conductive core of the via is constrained to thermally expand towards the second surface, away from the bus, thus preventing damage to the bus. The interlock may be a local constriction or enlargement of the via near the first surface of the substrate. The via may be greater in length along the bus than a unit spacing of beams in a parallel microswitch array actuated in unison along the bus. The via may be narrower in width than in length, and may form a trapezoidal geometry that is larger at the second surface of the substrate than at the first surface.

Abstract: An inorganic membrane device is provided. The device comprises a substrate having a network of pores, and a membrane layer at least partially coupled to the substrate and having a plurality of pores, wherein the pores have an aspect ratio in a range from about 1:2 to about 1:100.

Abstract: A flooring system comprising a plurality of elongate members (1) secured together along adjacent longitudinal side edges by means of co-operating male and female formations (2, 3). The female formation (3) is a channel with relatively convergent sidewalls and the male formation comprises a hollow rail of complementary shape. An outer sidewall of the channel is resilient to allow the rail to be snapped into the channel in a direction transverse to the length of the members (1) and to return to its original shape to resist removal of the rail. The formations (2, 3) are arranged so that upper surfaces of adjacent members (1) form a panel having a planar support surface (21) and relative rotation of the members (1) about an axis parallel to the longitudinal side edges is resisted. Two panels may be joined together to provide upper and lower planar support surfaces (21, 22).

Abstract: A method of making a membrane assembly is provided. The method comprises forming an inorganic membrane layer disposed on a substrate, and forming a plurality of macropores in the substrate at least in part using anodization. Further, a membrane assembly is provided. The membrane assembly comprises a filtering membrane that is coupled to an anodized substrate comprising a plurality of macropores.

Abstract: Methods and microfluidic devices for generating and manipulating sample droplets, wherein the devices comprise, a plurality of fluid channels, at least one of which is a sample channel for carrying a fluidic sample material, that is in fluid communication with the carrier fluid channel via an orifice; and an actuated flow interrupter adapted to force a predetermined amount of the sample fluid from the sample channel through the orifice into the carrier fluid channel.

Abstract: A MEMS switch includes a substrate, a movable actuator coupled to the substrate, a substrate contact, a substrate electrode, and a conductive stopper electrically coupled to the movable actuator and structured to prevent the movable actuator from contacting the substrate electrode while allowing the movable actuator to make contact with the substrate contact.

Abstract: Multiple microelectromechanical systems (MEMS) on a substrate are capped with a cover using a layer that may function as a bonding agent, separation layer, and hermetic seal. A substrate has a first side with multiple MEMS devices. A cover is formed with through-holes for vias, and with standoff posts for layer registration and separation. An adhesive sheet is patterned with cutouts for the MEMS devices, vias, and standoff posts. The adhesive sheet is tacked to the cover, then placed on the MEMS substrate and heated to bond the layers. The via holes may be metalized with leads for circuit board connection. The MEMS units may be diced from the substrate after sealing, thus protecting them from contaminants.

Abstract: A MEMS switch includes a substrate, a movable actuator coupled to the substrate, a substrate contact, a substrate electrode, and a conductive stopper electrically coupled to the movable actuator and structured to prevent the movable actuator from contacting the substrate electrode while allowing the movable actuator to make contact with the substrate contact.